Your search keyword '"Sperm Tail metabolism"' showing total 12 results

1. Hyperpolarization induces cytosolic alkalization of mouse sperm flagellum probably through sperm Na+/H+ exchanger.

Author

Hernández-Garduño S, Chávez JC, Matamoros-Volante A, Sánchez-Guevara Y, Torres P, Treviño CL, and Nishigaki T

Subjects

Animals, Humans, Hydrogen-Ion Concentration, Male, Mice, Semen, Valinomycin pharmacology, Sodium-Hydrogen Exchangers metabolism, Sperm Tail metabolism, Spermatozoa metabolism

Abstract

In Brief: Hyperpolarization of the membrane potential is a crucial step for mammalian sperm maturation. This work demonstrates that this membrane potential change likely activates a sperm-specific sodium/proton exchanger to induce alkalization in mouse sperm flagellum., Abstract: The sperm-specific sodium/proton exchanger (sNHE) is an indispensable protein for male fertility in mammals. Nevertheless, it is still unknown how mammalian sNHE is regulated. Evidence obtained from sea urchin sNHE indicates that hyperpolarization of plasma membrane potential (Vm), which is a hallmark of mammalian capacitation, positively regulates the sNHE. Therefore, we explored the activity of sNHE in mouse and human sperm by fluorescence imaging of intracellular pH (pHi) with a ratiometric dye, SNARF-5F. A valinomycin-induced Vm hyperpolarization elevated sperm flagellar pHi of WT mouse but not in sNHE-KO mouse. Moreover, this pHi increase was inhibited in a high K+ (40 mM) medium. These results support the idea that mouse sNHE is activated by Vm hyperpolarization. Interestingly, we observed different types of kinetics derived from valinomycin-induced alkalization, including some (30%) without any pHi changes. Our quantitative pHi determinations revealed that unresponsive cells had a high resting pHi (>7.5), suggesting that the activity of mouse sNHE is regulated by the resting pHi. On the other hand, valinomycin did not increase the pHi of human sperm in the head or the flagellum, regardless of their resting pHi values. Our findings suggest that the regulatory mechanisms of mammalian sNHEs are probably distinct depending on the species.

Published

2022

2. Formation and function of the manchette and flagellum during spermatogenesis.

Author

Lehti MS and Sironen A

Subjects

Animals, Humans, Male, Protein Transport, Flagella metabolism, Sperm Tail metabolism, Spermatids metabolism, Spermatogenesis physiology

Abstract

The last phase of spermatogenesis involves spermatid elongation (spermiogenesis), where the nucleus is remodeled by chromatin condensation, the excess cytoplasm is removed and the acrosome and sperm tail are formed. Protein transport during spermatid elongation is required for correct formation of the sperm tail and acrosome and shaping of the head. Two microtubular-based protein delivery platforms transport proteins to the developing head and tail: the manchette and the sperm tail axoneme. The manchette is a transient skirt-like structure surrounding the elongating spermatid head and is only present during spermatid elongation. In this review, we consider current understanding of the assembly, disassembly and function of the manchette and the roles of these processes in spermatid head shaping and sperm tail formation. Recent studies have shown that at least some of the structural proteins of the sperm tail are transported through the intra-manchette transport to the basal body at the base of the developing sperm tail and through the intra-flagellar transport to the construction site in the flagellum. This review focuses on the microtubule-based mechanisms involved and the consequences of their disruption in spermatid elongation., (© 2016 Society for Reproduction and Fertility.)

Published

2016

3. Haplo-deficiency of ODF1/HSPB10 in mouse sperm causes relaxation of head-to-tail linkage.

Author

Yang K, Grzmil P, Meinhardt A, and Hoyer-Fender S

Subjects

Animals, Genotype, Heat-Shock Proteins genetics, Heterozygote, Homozygote, Infertility, Male genetics, Infertility, Male pathology, Male, Mice, 129 Strain, Mice, Congenic, Mice, Inbred C57BL, Mice, Knockout, Phenotype, Sexual Behavior, Animal, Sperm Head ultrastructure, Sperm Motility, Sperm Tail ultrastructure, Fertility, Haploinsufficiency, Heat-Shock Proteins metabolism, Infertility, Male metabolism, Sperm Head metabolism, Sperm Tail metabolism

Abstract

The small heat shock protein ODF1/HSPB10 is essential for male fertility in mice. Targeted deletion of Odf1 resulted in acephalic sperm in homozygous mice of mixed background (C57BL/6J//129/Sv), whereas heterozygous animals are fully fertile. To further elucidate the function of ODF1, we generated incipient congenic mice with targeted deletion of Odf1 by successive backcrossing on the 129/Sv background. We observed that fecundity of heterozygous Odf1(+/-) male mice was severely reduced over backcross generations. However, neither aberrant sperm parameters nor sperm anomalies could be observed. Ultra-structural analyses of sperm from incipient congenic heterozygous Odf1(+/-) males of backcross generation N7 revealed no obvious pathological findings. However, we observed an enlargement of the distance between nuclear membrane and capitulum, indicating a weakening of the sperm head-to-tail coupling. Severe male subfertility provoked by haplo-deficiency of ODF1 is therefore most probably caused by impaired head-to-tail coupling that eventually might induce sperm decapitation on the specific conditions of in vivo fertilisation. As subfertility in haplo-deficient ODF1 male mice could not be diagnosed by semen analysis, it seems to be a paradigm for unexplained infertility that is a frequent diagnosis for male fertility impairment in humans., (© 2014 Society for Reproduction and Fertility.)

Published

2014

4. Season-induced variation in lipid composition is associated with semen quality in Holstein bulls.

Author

Argov-Argaman N, Mahgrefthe K, Zeron Y, and Roth Z

Subjects

Animals, Animals, Inbred Strains, Asthenozoospermia etiology, Asthenozoospermia metabolism, Asthenozoospermia pathology, Asthenozoospermia veterinary, Cattle, Cattle Diseases etiology, Cattle Diseases pathology, Cell Shape, Cholesterol analysis, Cholesterol metabolism, Fatty Acids analysis, Fatty Acids metabolism, Flame Ionization veterinary, Infertility, Male etiology, Infertility, Male metabolism, Infertility, Male pathology, Israel, Male, Seasons, Semen cytology, Semen Analysis veterinary, Sperm Head metabolism, Sperm Head pathology, Sperm Tail metabolism, Sperm Tail pathology, Cattle Diseases metabolism, Infertility, Male veterinary, Lipid Metabolism, Semen metabolism, Stress, Physiological

Abstract

Season-induced variation in fatty acid and cholesterol composition in bovine semen has been associated with semen quality. Given the specific roles of the various semen compartments (seminal fluids, sperm head, and sperm tail) in fertilization, we hypothesized that environmental-stress-induced alterations in the lipid composition of a specific compartment might impair semen quality and sperm function. Semen samples were collected from five mature Holstein-Friesian bulls during the summer (August to September) and winter (December to January). Semen was evaluated by computerized sperm-quality analyzer, calibrated for bulls' semen, and centrifuged to separate the spermatozoa from the seminal fluids. The spermatozoal fraction was sonicated to separate the sperm head and tail compartments. Cold lipid extraction was performed with chloroform:methanol (2:1, vol/vol). Lipids were identified and quantified by gas chromatography. Seasonal variation was found in both physiological and structural parameters. The proportion of spermatozoa defined as morphologically normal was higher in the winter, with higher motility, progressive motility, and velocity relative to summer samples. Lipid composition within fractions varied between seasons with prominent impairment in the tail compartment, characterized by high saturated fatty acid, low polyunsaturated fatty acid, and low cholesterol concentrations during the summer. Given the association between alterations in lipid composition and reduced sperm motility and velocity during the summer, it is suggested that lipid composition might serve to predict sperm quality.

Published

2013

5. Spermatid development in XO male mice with varying Y chromosome short-arm gene content: evidence for a Y gene controlling the initiation of sperm morphogenesis.

Author

Vernet N, Mahadevaiah SK, Ellis PJ, de Rooij DG, and Burgoyne PS

Subjects

Acrosome metabolism, Acrosome pathology, Animals, Chromosome Deletion, Chromosomes, Human, Y metabolism, Crosses, Genetic, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Eukaryotic Initiation Factor-2 genetics, Gene Deletion, Infertility, Male, Male, Meiosis, Mice, Mice, Knockout, Mice, Transgenic, Recombinant Fusion Proteins metabolism, Sex Chromosome Aberrations, Sex Chromosome Disorders of Sex Development pathology, Sex-Determining Region Y Protein genetics, Sperm Tail metabolism, Sperm Tail pathology, Spermatids pathology, Transcription Factors genetics, Transcription Factors metabolism, Disease Models, Animal, Eukaryotic Initiation Factor-2 metabolism, Genes, Y-Linked, Sex Chromosome Disorders of Sex Development metabolism, Sex-Determining Region Y Protein metabolism, Spermatids metabolism, Spermatogenesis

Abstract

We recently used three XO male mouse models with varying Y short-arm (Yp) gene complements, analysed at 30 days post partum, to demonstrate a Yp gene requirement for the apoptotic elimination of spermatocytes with a univalent X chromosome at the first meiotic metaphase. The three mouse models were i) XSxr(a)O in which the Yp-derived Tp(Y)1Ct(Sxr-a) sex reversal factor provides an almost complete Yp gene complement, ii) XSxr(b)O,Eif2s3y males in which Tp(Y)1Ct(Sxr-b) has a deletion completely or partially removing eight Yp genes - the Yp gene Eif2s3y has been added as a transgene to support spermatogonial proliferation, and iii) XOSry,Eif2s3y males in which the Sry transgene directs gonad development along the male pathway. In this study, we have used the same mouse models analysed at 6 weeks of age to investigate potential Yp gene involvement in spermiogenesis. We found that all three mouse models produce haploid and diploid spermatids and that the diploid spermatids showed frequent duplication of the developing acrosomal cap during the early stages. However, only in XSxr(a)O males did spermiogenesis continue to completion. Most strikingly, in XOSry,Eif2s3y males, spermatid development arrested at round spermatid step 7 so that no sperm head restructuring or tail development was observed. In contrast, in XSxr(b)O,Eif2s3y males, spermatids with substantial sperm head and tail morphogenesis could be easily found, although this was delayed compared with XSxr(a)O. We conclude that Sxr(a) (and therefore Yp) includes genetic information essential for sperm morphogenesis and that this is partially retained in Sxr(b).

Published

2012

6. Disruption of the murine dynein light chain gene Tcte3-3 results in asthenozoospermia.

Author

Rashid S, Grzmil P, Drenckhahn JD, Meinhardt A, Adham I, Engel W, and Neesen J

Subjects

Animals, Apoptosis genetics, Dyneins deficiency, Dyneins genetics, Dyneins metabolism, Epididymis pathology, Fallopian Tubes physiology, Female, Gene Targeting methods, Male, Mice, Mice, Knockout, Protein Isoforms genetics, Sperm Count, Sperm Head pathology, Sperm Motility genetics, Sperm Tail metabolism, Sperm Tail pathology, Sperm Transport, Spermatogenesis genetics, Spermatozoa abnormalities, Spermatozoa metabolism, Spermatozoa pathology, Testis metabolism, Testis pathology, Uterus physiology, Vacuoles pathology, Asthenozoospermia genetics, Asthenozoospermia physiopathology, Dyneins physiology

Abstract

To elucidate the role of the mouse gene Tcte3 (Tctex2), which encodes a putative light chain of the outer dynein arm of cilia and sperm flagella, we have inactivated this gene in mice using targeted disruption. Breeding of heterozygous males and females resulted in normal litter size; however, we were not able to detect homozygous Tcte3-deficent mice using standard genotype techniques. In fact, our results indicate the presence of at least three highly similar copies of the Tcte3 gene (Tcte3-1, Tcte3-2, and Tcte3-3) in the murine genome. Therefore, quantitative real-time PCR was established to differentiate between mice having one or two targeted Tcte3-3 alleles. By this approach, Tcte3-3(-/-) animals were identified, which were viable and revealed no obvious malformation. Interestingly, some homozygous Tcte3-3-deficient male mice bred with wild-type female produced no offspring while other Tcte3-3-deficient males revealed decreased sperm motility but were fertile. In infertile Tcte3-3(-/-) males, spermatogenesis was affected and sperm motility was reduced, too, resulting in decreased ability of Tcte3-3-deficient spermatozoa to move from the uterus into the oviduct. Impaired flagellar motility is not correlated with any gross defects in the axonemal structure, since outer dynein arms are detectable in sperm of Tcte3-3(-/-) males. However, in infertile males, deficient Tcte3-3 function is correlated with increased apoptosis during male germ cell development, resulting in a reduction of sperm number. Moreover, multiple malformations in developing haploid germ cells are present. Our results support a role of Tcte3-3 in generation of sperm motility as well as in male germ cell differentiation.

Published

2010

7. A-kinase anchoring protein 4 has a conserved role in mammalian spermatogenesis.

Author

Hu Y, Yu H, Pask AJ, O'Brien DA, Shaw G, and Renfree MB

Subjects

A Kinase Anchor Proteins chemistry, A Kinase Anchor Proteins metabolism, Amino Acid Sequence, Animals, Cloning, Molecular, Conserved Sequence, Macropodidae metabolism, Male, Molecular Sequence Data, RNA, Messenger metabolism, Sperm Tail metabolism, Spermatids metabolism, Testis metabolism, X Chromosome, A Kinase Anchor Proteins genetics, Macropodidae genetics, Spermatogenesis

Abstract

A-kinase anchor protein 4 (AKAP4) is an X-linked member of the AKAP family of scaffold proteins that anchor cAMP-dependent protein kinases and play an essential role in fibrous sheath assembly during spermatogenesis and flagellar function in spermatozoa. Marsupial spermatozoa differ in structural organization from those of eutherian mammals but data on the molecular control of their structure and function are limited. We therefore cloned and characterized the AKAP4 gene in a marsupial, the tammar wallaby (Macropus eugenii). The gene structure, sequence, and predicted protein of AKAP4 were highly conserved with that of eutherian orthologues and it mapped to the marsupial X-chromosome. There was no AKAP4 expression detected in the developing young. In the adult, AKAP4 expression was limited to the testis with a major transcript of 2.9 kb. AKAP4 mRNA was expressed in the cytoplasm of round and elongated spermatids while its protein was found on the principal piece of the flagellum in the sperm tail. This is consistent with its expression in other mammals. Thus, AKAP4 appears to have a conserved role in spermatogenesis for at least the last 166 million years of mammalian evolution.

Published

2009

8. Marine fish spermatozoa: racing ephemeral swimmers.

Author

Cosson J, Groison AL, Suquet M, Fauvel C, Dreanno C, and Billard R

Subjects

Adenosine Triphosphate metabolism, Animals, Axoneme metabolism, Energy Metabolism, Fishes metabolism, Male, Models, Biological, Seawater, Sperm Tail metabolism, Sperm Tail physiology, Spermatozoa metabolism, Fishes physiology, Sperm Motility physiology, Spermatozoa physiology

Abstract

After a long period of spermatogenesis (several weeks to months), marine fish spermatozoa are delivered at male spawning in seawater (SW) at the same time as ova. In some fish species, as the ova micropyle closes quickly after release, these minute unicells, the spermatozoa, have to accomplish their task of reaching the micropyle within a very brief period (several seconds to minutes), for delivery of the haploid male genetic information to the ova. To achieve this goal, their high-performance motile equipment, the flagellum, must fully activate immediately on contact with the SW and then propel the sperm cell at an unusually high initial velocity. The cost of such 'hyperactivity' is a very rapid consumption of intracellular ATP that outstrips the supply. The spermatozoa become rapidly exhausted because mitochondria cannot compensate for this very fast flagellar energy consumption. Therefore, any spermatozoon ends up with two possibilities: either becoming exhausted and immotile or reaching the egg micropyle within its very short period of forward motility (in the range of tens of seconds) before micropyle closure in relation to both contact of SW and cortical reaction. The aim of the present review is to present step by step the successive events occurring in marine fish spermatozoa from activation until their full arrest of motility. The present knowledge of activation mechanisms is summarized, as well as a description of the motility parameters characterizing the motility period. As a complement, in vitro results on axonemal motility obtained after demembranation of flagella bring further understanding. The description of the sperm energetic content (ATP and other high energy compounds) and its evolution during the swimming period is also discussed. A general model aiming to explain all the successive cellular events occurring immediately after the activation is presented. This model is proposed as a guideline for understanding the events governing the sperm lifespan in the marine fish species that reproduce through external fertilization.

Published

2008

9. Characterization of gametogenetin 1 (GGN1) and its potential role in male fertility through the interaction with the ion channel regulator, cysteine-rich secretory protein 2 (CRISP2) in the sperm tail.

Author

Jamsai D, Bianco DM, Smith SJ, Merriner DJ, Ly-Huynh JD, Herlihy A, Niranjan B, Gibbs GM, and O'Bryan MK

Subjects

Acrosome chemistry, Acrosome metabolism, Amino Acid Motifs, Amino Acid Sequence, Animals, Base Sequence, Blotting, Northern methods, Blotting, Western methods, Cell Adhesion Molecules, Cloning, Molecular, Genetic Engineering, Glycoproteins genetics, Glycoproteins metabolism, Immunohistochemistry, Male, Membrane Proteins, Mice, Molecular Sequence Data, Protein Binding, Sperm Motility physiology, Sperm Tail metabolism, Spermatids chemistry, Spermatids metabolism, Spermatocytes chemistry, Spermatocytes metabolism, Spermatogenesis physiology, Testicular Hormones genetics, Testicular Hormones metabolism, Testis metabolism, Two-Hybrid System Techniques, Glycoproteins analysis, Sperm Tail chemistry, Testicular Hormones analysis, Testis chemistry

Abstract

Cysteine-rich secretory protein 2 (CRISP2) is a testis-enriched protein localized to the sperm acrosome and tail. CRISP2 has been proposed to play a critical role in spermatogenesis and male fertility, although the precise function(s) of CRISP2 remains to be determined. Recent data have shown that the CRISP domain of the mouse CRISP2 has the ability to regulate Ca(2+) flow through ryanodine receptors (RyR) and to bind to MAP kinase kinase kinase 11 (MAP3K11). To further define the biochemical pathways within which CRISP2 is involved, we screened an adult mouse testis cDNA library using a yeast two-hybrid assay to identify CRISP2 interacting partners. One of the most frequently identified CRISP2-binding proteins was gametogenetin 1 (GGN1). Interactions occur between the ion channel regulatory region within the CRISP2 CRISP domain and the carboxyl-most 158 amino acids of GGN1. CRISP2 does not bind to the GGN2 or GGN3 isoforms. Furthermore, we showed that Ggn1 is a testis-enriched mRNA and the protein first appeared in late pachytene spermatocytes and was up-regulated in round spermatids before being incorporated into the principal piece of the sperm tail where it co-localized with CRISP2. These data along with data on RyR and MAP3K11 binding define the CRISP2 CRISP domain as a protein interaction motif and suggest a role for the GGN1-CRISP2 complex in sperm tail development and/or motility.

Published

2008

10. In spermatozoa, Stat1 is activated during capacitation and the acrosomal reaction.

Author

Bastián Y, Zepeda-Bastida A, Uribe S, and Mújica A

Subjects

Animals, Biological Transport, Blotting, Western methods, Calcium pharmacology, Cells, Cultured, Cyclic AMP-Dependent Protein Kinases antagonists & inhibitors, Cyclic AMP-Dependent Protein Kinases metabolism, Cytoplasm metabolism, Egtazic Acid pharmacology, Electrophoresis, Polyacrylamide Gel, Genistein pharmacology, Guinea Pigs, Indoles pharmacology, Isoflavones pharmacology, Isoquinolines pharmacology, Male, Maleimides pharmacology, Phosphorylation, Protein Kinase C antagonists & inhibitors, Protein Kinase C metabolism, Protein-Tyrosine Kinases antagonists & inhibitors, STAT1 Transcription Factor analysis, STAT4 Transcription Factor analysis, STAT4 Transcription Factor metabolism, Sperm Tail metabolism, Sulfonamides pharmacology, Acrosome Reaction physiology, STAT1 Transcription Factor metabolism, Sperm Capacitation physiology, Spermatozoa metabolism, Transcriptional Activation drug effects

Abstract

A role for sperm-specific proteins during the early embryonic development has been suggested by a number of recent studies. However, little is known about the participation of transcription factors in that stage. Here, we show that the signal transducer and activator of transcription 1 (Stat1), but not Stat4, was phosphorylated in response to capacitation and the acrosomal reaction (AR). Moreover, Stat1 phosphorylation correlated with changes in its localization: during capacitation, Stat1 moved from the cytoplasm to the theca/flagellum fraction. During AR, Stat1 phosphorylation increased again. In addition, blocking protein kinase A (PKA) and PKC during capacitation abolished both phosphorylation and migration of Stat1. Our results show tight spatio-temporal rearrangements of Stat1, suggesting that after fertilization Stat1 participates in the first rounds of transcription within the male pronucleus.

Published

2007

11. Deficiency of co-chaperone immunophilin FKBP52 compromises sperm fertilizing capacity.

Author

Hong J, Kim ST, Tranguch S, Smith DF, and Dey SK

Subjects

Animals, Blotting, Western, Epididymis chemistry, Epididymis metabolism, Female, Fertilization in Vitro, Fluorescent Antibody Technique, Indirect, Immunohistochemistry, In Situ Hybridization, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Receptors, Androgen analysis, Receptors, Androgen metabolism, Reverse Transcriptase Polymerase Chain Reaction, Sperm Tail chemistry, Sperm Tail metabolism, Spermatozoa cytology, Tacrolimus Binding Proteins analysis, Tacrolimus Binding Proteins genetics, Acrosome Reaction physiology, Molecular Chaperones, Spermatozoa metabolism, Tacrolimus Binding Proteins physiology

Abstract

FKBP52 is a member of the FK506-binding family of immunophilins and serves as a co-chaperone for steroid hormone nuclear receptors to govern appropriate hormone action in target tissues. Male mice missing Fkbp52 are infertile, and this infertility has been ascribed to compromised sensitivity of the anterior prostate, external genitalia, and other accessory sex organs to androgen. Here, we show additional defects contributing to infertility. We found that epididymal Fkbp52(-/-) sperm are sparse often with aberrant morphology, and they have reduced fertilizing capacity. This phenotype, initially observed in null males on a C57BL/6/129 background, is also maintained on a CD1 background. Expression studies show that while FKBP52 and androgen receptor are co-expressed in similar cell types in the epididymis, FKBP52 is also present in epididymal sperm flagella. Collectively, our results suggest that reduced number and abnormal morphology contribute to compromised fertilizing capacity of Fkbp52(-/-) sperm. This study is clinically relevant because unraveling the role of immunophilin signaling in male fertility will help identify new targets for male contraceptives and/or alleviate male infertility.

Published

2007

12. Expression and subcellular localization of the mu-opioid receptor in equine spermatozoa: evidence for its functional role.

Author

Albrizio M, Guaricci AC, Maritato F, Sciorsci RL, Mari G, Calamita G, Lacalandra GM, Aiudi GG, Minoia R, Dell'Aquila ME, and Minoia P

Subjects

Acrosome Reaction, Animals, Base Sequence, Cattle, Cell Membrane metabolism, Dose-Response Relationship, Drug, Fluorescent Antibody Technique, Humans, Immunoblotting, Male, Microscopy, Confocal, Molecular Sequence Data, Naloxone pharmacology, Narcotic Antagonists pharmacology, Rats, Receptors, Opioid, mu analysis, Receptors, Opioid, mu genetics, Sequence Alignment, Sperm Capacitation drug effects, Sperm Head chemistry, Sperm Head metabolism, Sperm Motility drug effects, Sperm Tail chemistry, Sperm Tail metabolism, Sperm Transport drug effects, Spermatozoa chemistry, Staining and Labeling, Horses metabolism, Receptors, Opioid, mu metabolism, Spermatozoa metabolism

Abstract

The development of fertilizing ability in sperm cells is associated with changes in the plasma membrane. However, to date the exact nature of sequentially activated primary receptors and channels and the signal transduction pathways derived from these remains elusive. We analyzed the expression and localization of the mu-opioid receptor in equine spermatozoa. A transcript corresponding to the third extracellular loop that selectively binds mu agonists was amplified, sequenced and compared with the known sequences in humans, rats and cattle. The amplification product showed a high degree of nucleotide conservation. By immunofluorescence, mu-opioid receptor labeling was found on the sperm head and on the tail and disappeared in the acrosomal region of acrosome-reacted sperm cells. Immunoblotting revealed two bands of 50 and 65 kDa. Effects of the opioid antagonist naloxone on motility and on viability and capacitation/acrosome reaction were investigated by computer-assisted sperm analysis and Hoechst 33258/chlortetracycline (H258/CTC) staining. Progressive motility was significantly reduced after 3 h incubation in 10(-3) M naloxone (P <0.05), whereas it increased significantly after 5 h in 10(-8) M naloxone (P <0.05). Sperm velocity at 5 h was significantly reduced by the addition of 10(-3) M naloxone (P <0.05), but increased significantly in the presence of 10(-8) M (P <0.001). Curvilinear velocity and amplitude of lateral head displacement in spermatozoa incubated in the presence of naloxone were not indicative of hyperactivation. H258/CTC staining showed that 10(-8) M naloxone significantly stimulated capacitation (P <0.01) after 3 h. However, it had no effect on sperm cell viability and acrosomal status. Overall, this study provides the first evidence that the mu-opioid receptor is expressed in equine spermatozoa and that naloxone significantly affects motility and capacitation.

Published

2005